# How can I map a list of ranges to a single value?

I've only recently jumped into the world of iphone development and objective-c, so I'm still a bit lost as to how I might implement something like this.

I have a float, and I have a list of ranges that float can fall within and the corresponding value I should return, eg:

``````10.0 - 14.5 : 1.0
14.5 - 17.0 : 2.0
17.0 - 23.0 : 2.5
23.0 - 32.4 : 4.0
``````

So if my float is, say, 15.12, I want to return 2.0.

The part that makes this tricky is that the range list is quite long, and I have several such range lists that I need to choose from, any of which might need to be changed later. Simply writing a few hundred or thousand `if` statements seems like an ugly solution to say the least.

-

Essentially what you are describing is Fuzzy Logic.

I wrote you a fuzzy logic rules class which should handle what you are wanting to do.

Features:

• You can add your own custom rules easily with a method I've provided.
• You can check a value with a single `method` and get a string result (or `nil` if it matches no rules).
• As it uses rules you can define whatever interval periods you wish.

``````[logic addRule:@"2.0" forLowerCondition:14.5 forUpperCondition:17.0];
``````

Sample output (from the code below):

``````Result for 15.20 is: 2.0
``````

Here is the code implementation.....

``````FuzzyLogic *logic = [[FuzzyLogic alloc] initWithRule:@"1.0" forLowerCondition:10.0 forUpperCondition:14.5];

double input1 = 15.2f;

NSLog(@"Result for %.2lf is: %@", input1, [logic fuzzyResultForValue:input1]);

[logic release];
``````

FuzzyLogic.h:

``````#import <Foundation/Foundation.h>

@interface FuzzyLogic : NSObject {
NSMutableArray *conditions;
}

- (id) initWithRule:(NSString*)result forLowerCondition:(double)lower forUpperCondition:(double)upper;
- (NSString*) fuzzyResultForValue:(double)input;

@end
``````

FuzzyLogic.m:

``````#import "FuzzyLogic.h"

@implementation FuzzyLogic

enum {
lowerIndex = 0,
upperIndex,
resultIndex
};

- (id) initWithRule:(NSString*)result forLowerCondition:(double)lower forUpperCondition:(double)upper {
self = [super init];
if (self != nil) {
}
return self;
}

- (void) addRule:(NSString*)result forLowerCondition:(double)lower forUpperCondition:(double)upper {

NSArray *rule = [[NSArray alloc] initWithObjects:[NSString stringWithFormat:@"%lf",lower],[NSString stringWithFormat:@"%lf",upper],result,nil];

if (conditions == nil) {
conditions = [[NSMutableArray alloc] initWithObjects:rule,nil];
} else {
}
}

- (NSString*) fuzzyResultForValue:(double)input
{
NSString *returnable = nil;

// Find the result
for (NSArray *cond in conditions) {
double lower = [[cond objectAtIndex:lowerIndex] doubleValue];
double upper = [[cond objectAtIndex:upperIndex] doubleValue];
if ( (input >= lower && input < upper) ) {
returnable = [cond objectAtIndex:resultIndex];
break;
}
}

if (returnable == nil)
{ NSLog(@"Error: Input met no conditions!");}
return returnable;
}

@end
``````
-

If the ranges are all adjacent, you could make a custom collection class for this, and implement it with two parallel arrays of numbers.

Each number in the first array is one end of one or two ranges:

• 10.0
• 14.5
• 17.0
• 23.0
• 32.4

The second array holds one fewer number; these numbers are the values to map to:

• 1.0
• 2.0
• 2.5
• 4.0

Your implementation of searching this collection would consist of comparing a requested key number to each number in the keys array and the number after it. It'd be simplest to implement a linear search, at least at first (you can optimize it later with Instruments's or Shark's guidance). For example, say this object is asked about 20:

• 10.0 ≤ 20 < 14.5? No.
• 14.5 ≤ 20 < 17.0? No.
• 17.0 ≤ 20 < 23.0? Yes.

Having found that the requested key value is within the third range, you return the third value (2.5).

-
No reason you couldn't. That's an implementation detail; the questioner can implement a linear search to get it working (at least long enough to write unit tests to prove that), then change it to a partitioned search if Instruments or Shark or timing the test cases confirms that a linear search is not fast enough. –  Peter Hosey Aug 24 '10 at 8:06
(Previous comment was in response to a question of why not use binary search instead of linear.) I see this answer has picked up a downvote; would whoever gave it please explain why? –  Peter Hosey Aug 24 '10 at 17:07